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www.medscape.com
From Nature Reviews Endocrinology
Stress and Disorders of the Stress
System
George P. Chrousos
Posted: 07/21/2009; Nat Rev Endocrinol. 2009;5(7):374-381. © 2009 Nature Publishing Group
Abstract and Introduction
Abstract
All organisms must maintain a complex dynamic equilibrium, or homeostasis, which is constantly challenged by
internal or external adverse forces termed stressors. Stress occurs when homeostasis is threatened or perceived to
be so; homeostasis is re-established by various physiological and behavioral adaptive responses. Neuroendocrine
hormones have major roles in the regulation of both basal homeostasis and responses to threats, and are involved
in the pathogenesis of diseases characterized by dyshomeostasis or cacostasis. The stress response is mediated
by the stress system, partly located in the central nervous system and partly in peripheral organs. The central,
greatly interconnected effectors of this system include the hypothalamic hormones arginine vasopressin,
corticotropin-releasing hormone and pro-opiomelanocortin-derived peptides, and the locus ceruleus and autonomic
norepinephrine centers in the brainstem. Targets of these effectors include the executive and/or cognitive, reward
and fear systems, the wake–sleep centers of the brain, the growth, reproductive and thyroid hormone axes, and the
gastrointestinal, cardiorespiratory, metabolic, and immune systems. Optimal basal activity and responsiveness of
the stress system is essential for a sense of well-being, successful performance of tasks, and appropriate social
interactions. By contrast, excessive or inadequate basal activity and responsiveness of this system might impair
development, growth and body composition, and lead to a host of behavioral and somatic pathological conditions.
Introduction
"Hypothalamic hypophysiotropic factors" were originally proposed by G. W. Harris in the 1940s; since then, a
substantial body of evidence has confirmed that these factors do indeed exist.[1-3] The survival of complex
organisms—at both the individual and species levels—relies on these factors, which include mediators that regulate
homeostasis and influence behavior, energy metabolism, growth, reproduction and immunity. This Review provides
a brief, albeit comprehensive, synthesis of information on the conceptual evolution, technological advances and
current understanding of homeostasis and stress, and describes the salutogenic changes or pathogenic
disturbances that are associated with eustress or distress, respectively. This article is divided into three parts: the
first discusses the concepts related to homeostasis and stress, the second details the mediators and mechanisms of
the stress response, and the third describes the effects of stress on an organism.
Concepts of Homeostasis and Stress
All living organisms maintain a complex dynamic equilibrium, or homeostasis, which is constantly challenged by
internal or external adverse effects, termed stressors.[4,5] Thus, stress is defined as a state in which homeostasis is
actually threatened or perceived to be so; homeostasis is re-established by a complex repertoire of behavioral and
physiological adaptive responses of the organism. The development of concepts of homeostasis and stress is
summarized in Box 1 .
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Box 1 History of stress
The term stress originates from the Indo–European root 'str', which has been historically associated with
exertion of pressure. Thus, both the Greek 'strangalizein' and its English derivative and synonym 'to
strangle', as well as the Latin 'strigere' (to tighten), have their origins in the very distant past. The concept of
homeostasis as the general principle of balance or equilibrium of life was first enunciated clearly by the
ancient Greek natural philosophers, who called it 'harmony' (Pythagoras) or 'isonomia' (Alkmaeon).[4,75] The
modern synonym 'homeostasis', which means steady state, was coined by the American physiologist walter
Cannon in the beginning of the 20th century, whereas the word 'stress' was first used with its current
meaning and popularized by the Hungarian Canadian experimentalist Hans selye a few decades later. Both
Cannon and selye employed Hooke's law of elasticity to heuristically and creatively extrapolate physical
concepts into biology.[76–81]
Stressors comprise a long list of potentially adverse forces, which can be emotional or physical. Both the magnitude
and chronicity of stressors are important. When any stressor exceeds a certain severity or temporal threshold, the
adaptive homeostatic systems of the organism activate compensatory responses that functionally correspond to the
stressor. The stress system has a major role in coordination of this process ( Box 2 ).[2,3] The stress syndrome is a
relatively stereotypic, innate response that has evolved to co-ordinate homeostasis and protect the organism during
acute stress. Changes take place in the central nervous system (CNS) and in various peripheral organs and tissues.
In the CNS, the stress response includes facilitation of neural pathways that subserve acute, time-limited adaptive
functions, such as arousal, vigilance and focused attention, and inhibition of neural pathways that subserve acutely
nonadaptive functions, such as eating, growth and reproduction. In addition, stress-related changes lead to
increased oxygenation and nutrition of the brain, heart and skeletal muscles, which are all organs crucial to the
central coordination of the stress response and the 'fight or flight' reaction.
2
Box 2 Central and peripheral functions of the stress response
Functions of the central nervous system
• Facilitation of arousal, alertness, vigilance, cognition, attention and aggression
• Inhibition of vegetative functions (e.g. reproduction, feeding, growth)
• Activation of counter-regulatory feedback loops
Peripheral functions
•
•
•
•
•
•
Increase of oxygenation
Nutrition of brain, heart and skeletal muscles
Increase of cardiovascular tone and respiration
Increase of metabolism (catabolism, inhibition of reproduction and growth)
Increase of detoxification of metabolic products and foreign substances
Activation of counter-regulatory feedback loops (includes immunosuppression)
Homeostatic mechanisms, including the stress system, exert their effects in an inverted U-shaped dose–response
curve (Figure 1). Basal, healthy homeostasis (or eustasis) is achieved in the central, optimal range of the curve.
Suboptimal effects may occur on either side of the curve and can lead to insufficient adaptation, a state that has
been called allostasis (different homeostasis) or, more correctly, cacostasis (defective homeostasis,
dyshomeostasis, distress), which might be harmful for the organism in the short term and/or long term.[2,3] Both
hypofunction and hyperfunction of the homeostatic systems of the organism have multiple adverse effects. For
instance, both defective and excessive reactions to fear entail a decreased ability to survive of the individual and the
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species. Thus, both fearless, uninhibited individuals and fearful, excessively inhibited individuals have increased
risks of morbidity and mortality, the former as a result of underestimating danger, the latter as a result of decreased
social integration.
Figure 1 Homeostatic systems exert their effects in an inverse, U-type dose response.[2] Eustasis is in the
middle, optimal range of the curve. Suboptimal effects may be on either side of the curve and can lead to
suboptimal adaptation, termed allostasis or, more correctly, cacostasis, which may be harmful for the organism
in the short term or long term.
Eustasis is in the middle, optimal range of the curve. Suboptimal effects may be on either side of the curve and can
lead to suboptimal adaptation, termed allostasis or, more correctly, cacostasis, which may be harmful for the
organism in the short term or long term.
The interaction between homeostasis-disturbing stressors and stressor-activated adaptive responses of the
organism can have three potential outcomes. First, the match may be perfect and the organism returns to its basal
homeostasis or eustasis; second, the adaptive response may be inappropriate (for example, inadequate, excessive
and/or prolonged) and the organism falls into cacostasis; and, third, the match may be perfect and the organism
gains from the experience and a new, improved homeostatic capacity is attained, for which I propose the term
'hyperstasis'.
Mediators of Homeostasis and Stress
Stress mediators, which include the classic neuroendocrine hormones of the stress system, but also several other
neurotransmitters, cytokines and growth factors, regulate both basal and threatened homeostasis and might mediate
the pathogenesis of dyshomeostasis-related diseases.[2,6-8] Pivotal to our understanding of these mediators and their
effects on the human organism in health and disease has been the above-mentioned concept of hypothalamic
hypophysiotropic factors.
Central and Peripheral Effectors
The principal, greatly interconnected CNS effectors of the stress system, include the hypothalamic hormones
arginine vasopressin (AVP), corticotropin-releasing hormone (CRH), the pro-opiomelanocortin-derived peptides a-
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melanocyte-stimulating hormone and ß-endorphin, and norepinephrine produced in the A1/A2 centers of the
brainstem's locus ceruleus and in the central, autonomic nervous system.[2,3] Of note, other ascending aminergic
pathways, such as the serotonergic pathways that originate from the midbrain (nuclei raphe) and the posterior
hypothalamic histaminergic systems, accompany the locus ceruleus-derived norepinephrine central stress response
through secretion of 5-hydroxytryptamine and histamine, respectively.
The principal peripheral effectors are glucocorticoids, which are regulated by the hypothalamic–pituitary–adrenal
axis, and the catecholamines norepinephrine and epinephrine, which are regulated by the systemic and
adrenomedullary sympathetic nervous systems. Interestingly, postganglionic sympathetic nerve fibers also secrete
CRH, among other substances, whereas both catecholamines stimulate interleukin (IL-) 6 release by immune cells
and other peripheral cells via ß-adrenergic receptors.[8-10] The targets of all these stress mediators include the
executive and/or cognitive, the fear/anger and reward systems, the wake–sleep centers of the brain, the growth,
reproductive and thyroid-hormone axes, as well as the gastrointestinal, cardiorespiratory, metabolic, and immune
systems.
The Roles of Corticotropin-releasing Hormone
Shortly after isolation and sequencing of the 41 amino acid CRH in the mid-1980s,[11] researchers showed that when
this neuropeptide, which does not cross the blood–brain barrier, was injected into the cerebral ventricles of
experimental animals, it could reproduce the stress response summarized in Box 2 .[2,7,12] A series of subsequent
studies showed that the hypothalamic CRH–AVP and brainstem norepinephrine centers of the stress system
mutually innervate and stimulate each other.[2,7,12] This mutually reinforcing positive-feedback system could,
therefore, be activated by CRH, norepinephrine or any other stimulus that could set into motion either side of this
highly complex, but integrated, brain loop.
2
Box 2 Central and peripheral functions of the stress response
Functions of the central nervous system
• Facilitation of arousal, alertness, vigilance, cognition, attention and aggression
• Inhibition of vegetative functions (e.g. reproduction, feeding, growth)
• Activation of counter-regulatory feedback loops
Peripheral functions
•
•
•
•
•
•
Increase of oxygenation
Nutrition of brain, heart and skeletal muscles
Increase of cardiovascular tone and respiration
Increase of metabolism (catabolism, inhibition of reproduction and growth)
Increase of detoxification of metabolic products and foreign substances
Activation of counter-regulatory feedback loops (includes immunosuppression)
The stress system interacts with, influences and is influenced by several systems in the brain that serve cognitive
and/or executive, fear and anger and reward functions; these systems form a complex, integrated, positive and
negative feedback-system loop.[2,7,12-20] Furthermore, the stress system acutely and in a temporally limited fashion
activates the central nucleus of the amygdala, which has its own CRH system involved in the generation of fear
and/or anger; in return, the central nucleus of the amygdala stimulates the stress system and forms a mutually
reinforcing positive-feedback loop.[13,14] This system also activates (acutely and transiently) the mesolimbic,
dopaminergic reward system (which links the ventral tegmental area to the nucleus accumbens) and the
mesocortical, dopaminergic system (which links the ventral tegmentum to the frontal–prefrontal lobe), whereas it
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receives inhibitory input from the latter.[16-19] Finally, the stress system acutely activates the hippocampus—an organ
that has a major role in intermediate-term memory—whereas it receives negative input, partly as negative feedback
from the circulating glucocorticoids of the hypothalamic–pituitary–adrenal axis to its hypothalamic center, the
paraventricular nucleus, and partly as tonic, hippocampal inhibitory input upon the stress system.[20]
Arousal and Sleep
Activation of the stress system stimulates arousal and suppresses sleep;[12] conversely, loss of sleep is associated
with inhibition of the stress system. Interestingly, sleep loss is also associated with elevated level of circulating IL-6
in spite of the reduced stimulatory effect of catecholamines on IL-6 secretion; this change possibly results from the
concurrently decreased cortisol-mediated inhibition.[21-26]
Metabolism
During acute stress, the heart rate and arterial blood pressure are increased, while gluconeogenesis,
glycogenolysis, lipolysis and hepatic glucose secretion are stimulated, owing to elevated levels of catecholamines
and cortisol ( Box 2 ).
2
Box 2 Central and peripheral functions of the stress response
Functions of the central nervous system
• Facilitation of arousal, alertness, vigilance, cognition, attention and aggression
• Inhibition of vegetative functions (e.g. reproduction, feeding, growth)
• Activation of counter-regulatory feedback loops
Peripheral functions
•
•
•
•
•
•
Increase of oxygenation
Nutrition of brain, heart and skeletal muscles
Increase of cardiovascular tone and respiration
Increase of metabolism (catabolism, inhibition of reproduction and growth)
Increase of detoxification of metabolic products and foreign substances
Activation of counter-regulatory feedback loops (includes immunosuppression)
Growth, Reproduction and Thyroid Function
The growth, reproductive and thyroid-hormone axes are inhibited at several levels by stress mediators, whereas
estradiol and thyroid hormones stimulate the stress system.[2,7,12,27]
Gastrointestinal Function
During stress, the gastrointestinal system is inhibited at the level of the stomach via the vagus nerve, while being
stimulated at the level of the large bowel via the sacral parasympathetic system, which is activated by brainstemderived norepinephrine.[12,28]
The Immune System
Stress has complex effects on the immune system and influences both innate and acquired immunity.[6,8,9,29-31]
Glucocorticoids and catecholamines influence trafficking and/or function of leukocytes and accessory immune cells
and suppress the secretion of proinflammatory cytokines (tumor necrosis factor [TNF], IL-1, IL-6, IL-8 and IL-12),
whereas both hormone families induce a systemic switch from a TH1 response (that is, cellular immunity) to a TH2
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response (humoral immunity). Conversely, proinflammatory cytokines stimulate the stress system, also at multiple
levels, in both the CNS and peripheral nervous system, including the hypothalamus, central noradrenergic system,
pituitary and adrenal glands, which increases glucocorticoid levels and consequently suppresses the inflammatory
reaction. These actions form another important negative-feedback loop that protects the organism from overshoot of
the inflammatory response.
Peripheral secretion of 'authentic' CRH (originally described as 'immune' CRH because of its inflammatory actions)
by postganglionic sympathetic neurons and norepinephrine-activated release of IL-6 by peripheral immune cells and
other cells, respectively, lead to degranulation of mast cells (that is, the release of inflammatory and vasoactive
molecules from their secretory vesicles) in several tissues and activates the sickness syndrome.[6,8,9,31-33] The
former action represents an important component of the neurogenic inflammatory response, whereas the sickness
syndrome results from innate processes of the organism that are triggered and sustained by a systemic,
inflammatory reaction. The syndrome includes somnolence, fatigue, nausea and depressive mood; these symptoms
occur concurrently with activation of the acute-phase reaction by the liver and stimulation of the sensory-afferent
nervous system, which manifests as hyperalgesia and fatigue.
Cortisol is a greatly pleiotropic hormone that influences up to 20% of the expressed human genes and affects all
major homeostatic systems of the body, including innate and acquired immunity.[34-36] Of great interest are the
mutual interactions of the multiple isoforms of the activated glucocorticoid receptor with several transcription factors,
such as AP-1, COUP-TF1, NF?B, and the STATs, through which various brain functions, growth, immunity and
metabolism are regulated in a coordinated and highly stochastic fashion.[34-36]
Stress-system Disorders
The stress system has a basal circadian activity and also responds to stressors on demand.[2-5] Appropriate basal
activity, as well as quantitatively and temporally tailored responsiveness of the stress system to stressors, is
essential for a sense of well-being, adequate performance of tasks and positive social interactions. On the other
hand, inappropriate basal activity and/or responsiveness of the stress system, in terms of both magnitude and
duration, might impair growth, development and body composition, and might account for many behavioral,
endocrine, metabolic, cardiovascular, autoimmune, and allergic disorders. The development and severity of these
conditions depend on the genetic, epigenetic and constitutional vulnerability or resilience of the individual to stress,
their exposure to stressors during 'critical periods' of development, the presence of concurrent adverse or protective
environmental factors, and the timing, magnitude and duration of stress.
Prenatal development, infancy, childhood and adolescence are times of increased vulnerability to stressors. The
presence of stressors during these critical periods can have prolonged effects, such as sustained cacostasis that
can last the entire lifetime of an individual. These effects are determined constitutionally and/or epigenetically and
are (to a large extent) mediated by stress hormones, such as CRH and cortisol, that have profound effects on the
brain's stress response (Figure 2).[2,37-40] Naturally, during these same critical periods, individuals are similarly
sensitive to propitious environments, which induce hyperstasis and lead to the development of resistance to
stressors in adulthood.
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Figure 2 Chronic stress can lead to development of the metabolic syndrome.35
Abbreviations: ABP, arterial blood pressure; ACTH, adrenocorticotropic hormone; APR, acute-phase reactants;
AVP, arginine vasopressin; CRH, corticotropin-releasing hormone; iCRH, immune CRH; E, epinephrine; E2,
estradiol; GH, growth hormone; HPA, hypothalamic-pituitary-adrenal; IGF-I, insulin-like growth factor I; IL-6,
interleukin 6; LC, locus ceruleus; LH, luteinizing hormone; NE, norepinephrine; T, testosterone; TG, triglycerides.
Acute and Chronic Stress-related Diseases
Through its mediators, stress can lead to acute or chronic pathological, physical and mental conditions in individuals
with a vulnerable genetic, constitutional and/or epigenetic background.[3-10,20,36] Acute stress may trigger allergic
manifestations, such as asthma, eczema or urticaria, angiokinetic phenomena, such as migraines, hypertensive or
hypotensive attacks, different types of pain (such as headaches, abdominal, pelvic and low-back pain),
gastrointestinal symptoms (pain, indigestion, diarrhea, constipation), as well as panic attacks and psychotic
episodes. Chronic stress may cause physical, behavioral and/or neuropsychiatric manifestations: anxiety,
depression, executive and/or cognitive dysfunction; cardiovascular phenomena, such as hypertension; metabolic
disorders, such as obesity, the metabolic syndrome, and type 2 diabetes mellitus; atherosclerotic cardiovascular
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disease; neurovascular degenerative disease; osteopenia and osteoporosis; and sleep disorders, such as insomnia
or excessive daytime sleepiness.
The pathogenesis of acute-stress-induced disorders can be attributed to increased secretion and effects of the
major stress mediators in the context of a vulnerable background.[2,3,9,30-33] Thus, acute allergic attacks may be
activated by immune-CRH-induced degranulation of mast cells in the vulnerable organ (for example the lungs or
skin). These reactions cause asthma or eczema, respectively. Similarly, migraine headaches could be caused by
immune-CRH-induced degranulation of mast cells in meningeal blood vessels, which causes local vasodilatation
and increased permeability of the blood-brain barrier; panic or psychotic attacks could be triggered by CRH bursts in
the central amygdala that activate a fear response; hypertensive or hypotensive attacks could be caused by stressinduced, excessive sympathetic or parasympathetic system outflow, respectively.
The pathogenesis of chronic-stress-related disorders can also be explained by sustained, excessive secretion and
effects of the major mediators of stress and sickness syndromes, which influence the activities of multiple
homeostatic systems.[2,3,9,30-36] These disorders thus represent chronic, maladaptive effects of two physiological
processes whose mediators are meant to be secreted in a quantity-limited and time-limited fashion but have gone
awry. The negative consequences of these effects are both behavioral and somatic.
Behavioral and Somatic Consequences
The behavioral consequences of chronic stress result from continuous or intermittent activation of the stress and
sickness syndromes, and prolonged secretion of their mediators.[2,7,8,12,41-47] Thus, CRH, norepinephrine, cortisol
and other hormones activate the fear system, which produces anxiety, anorexia or hyperphagia; the same mediators
cause tachyphylaxis of the reward system, which produces depression and cravings for food, other substances or
stress. These mediators also suppress the sleep system, which causes insomnia, loss of sleep and daytime
somnolence. On the other hand, IL-6 and other mediators, possibly in synergy with those mentioned above,
generate fatigue, nausea, headaches and other pains. Executive and cognitive systems also malfunction as a result
of prolonged, chronic activation of stress and sickness syndromes and people may perform and plan suboptimally
and make and pursue the wrong decisions. A vicious cycle is initiated and sustained, in which behavioral
maladjustment leads to psychosocial problems in the family, peer group, school and/or work, which sustain or cause
further mediator changes and exacerbate behavioral maladjustment. The young, developing brain is particularly
vulnerable, as it lacks prior useful experiences to which it can resort.
The somatic consequences of continuous or intermittent activation of the stress and sickness syndromes can be
equally devastating (or even worse) than their behavioral consequences.[2,3,7,8,27,31,41-47] In developing children,
growth may be suppressed as a result of a hypofunctioning growth hormone axis; in adults, stress-induced
hypogonadism can manifest as loss of libido and/or hypofertility, and hyperactivity of the sympathetic system can
lead to essential hypertension. Chronic hypersecretion of stress mediators, in individuals with a vulnerable
background exposed to a permissive environment, may lead to visceral fat accumulation as a result of chronic
hypercortisolism, reactive insulin hypersecretion, low growth-hormone secretion and hypogonadism (Figure 2).
[2,3,27,47-52]
These same hormonal changes lead to sarcopenia, osteopenia and/or osteoporosis. Visceral obesity and
sarcopenia are associated with manifestations of the metabolic-syndrome, such as dyslipidemia (elevated levels of
total cholesterol, triglycerides and LDL-cholesterol and decreased level of HDL-cholesterol), hypertension and
carbohydrate intolerance or type 2 diabetes mellitus. Genetically or constitutionally vulnerable women of
reproductive age may develop polycystic ovary syndrome. Stress-related IL-6 hypersecretion plus adipose-tissuegenerated inflammatory hypercytokinemia, as well as hypercortisolism, contribute to increased production of acutephase reactants and blood hypercoagulation.[49-52] Insulin resistance, hypertension, dislipidemia, hypercytokinemia
and blood hypercoagulation lead to endothelial dysfunction and consequently atherosclerosis, with its cardiovascular
and neurovascular sequelae.
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Chronic-stress-induced immune dysfunction, primarily the TH1 to TH2 switch, increases the vulnerability of
individuals to certain infections and autoimmune disorders (Figure 1).[6-8,29-31,34] For instance, the immune
dysfunction observed in individuals who are chronically stressed might contribute to the persistence of infection with
Helicobacter pylori, granted that this pathogen primarily induces and is defended against through activation of a
cellular immune response. The same is true for infections with Mycobacterium tuberculosis and the common cold
viruses. Similarly, this switch increases vulnerability to TH2-driven autoimmune diseases, such as Graves disease,
systemic lupus erythematosus and some allergic conditions. Increased vulnerability to certain neoplasms and their
progression might be another effect of chronic stress, but this issue remains controversial.
Increased levels of CRH and/or stress-system abnormalities have been reported in behavioral and neuropsychiatric
disorders, such as hypothalamic oligomenorrhea and amenorrhea, reduced fertility, obligate athleticism, anxiety,
depression, post-traumatic stress disorder in children, eating disorders and chronic, active alcoholism ( Box 3 ).
[2,3,27,53-55]
On the other hand, overproduction of CRH in the brain and in peripheral tissues, as well as disruption of
the hypothalamic-pituitary-adrenal axis and the functions of the arousal and sympathetic systems, have been
reported in obesity, metabolic syndrome and essential hypertension. Furthermore, dysregulation of the stresssystem and autonomic nervous system is a distinctive feature of common gastrointestinal disorders, such as irritable
bowel syndrome and peptic ulcer disease.[56]
2
Box 3 Conditions with altered HPA axis activity
Increased activity of the HPA axis
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Cushing syndrome
Chronic stress
Melancholic depression
Anorexia nervosa
Obsessive-compulsive disorder
Panic disorder
Excessive exercise (obligate athleticism)
Chronic, active alcoholism
Alcohol and narcotic withdrawal
Diabetes mellitus
Central obesity (metabolic syndrome)
Post-traumatic stress disorder in children
Hyperthyroidism
Pregnancy
Decreased activity of HPA axis
•
•
•
•
•
•
•
•
•
•
•
Adrenal insufficiency
Atypical/seasonal depression
Chronic fatigue syndrome
Fibromyalgia
Premenstrual tension syndrome
Climacteric depression
Nicotine withdrawal
Following cessation of glucocorticoid therapy
Following Cushing syndrome cure
Following chronic stress
Postpartum period
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•
•
•
•
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Adult post-traumatic stress disorder
Hypothyroidism
Rheumatoid arthritis
Asthma, eczema
Abbreviation: HPA, hypothalamic–pituitary–adrenal.
Consistent with the observation that central or peripheral hypersecretion of CRH seems to be involved in a large
number of behavioral and somatic disorders, preclinical and clinical evidence suggests therapeutic potential for CRH
type 1 receptor antagonists, such as antalarmin, in the treatment of all or some of these diseases and other
neuropsychiatric and somatic entities.[57-62]
Abnormal neuroendocrine, autonomic and immune functions are also present in chronic inflammatory and/or
autoimmune and allergic diseases, in fibromyalgia and chronic fatigue syndromes; substantial evidence
demonstrates that these abnormalities are related to low CRH activity ( Box 3 ).[2,6-8,29-31,34,63] Similarly, low CRH
activity has been implicated in atypical, seasonal depression, postpartum 'baby blues' and depression, premenstrual
dysphoric disorder and climacteric depression.[2,3,27,64-67] In all these disorders, the problem seems to be cacostasis
secondary to inadequate stress-system activity and responsiveness, which influence the functions of the
homeostatic systems.
2
Box 3 Conditions with altered HPA axis activity
Increased activity of the HPA axis
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Cushing syndrome
Chronic stress
Melancholic depression
Anorexia nervosa
Obsessive-compulsive disorder
Panic disorder
Excessive exercise (obligate athleticism)
Chronic, active alcoholism
Alcohol and narcotic withdrawal
Diabetes mellitus
Central obesity (metabolic syndrome)
Post-traumatic stress disorder in children
Hyperthyroidism
Pregnancy
Decreased activity of HPA axis
•
•
•
•
•
•
•
•
Adrenal insufficiency
Atypical/seasonal depression
Chronic fatigue syndrome
Fibromyalgia
Premenstrual tension syndrome
Climacteric depression
Nicotine withdrawal
Following cessation of glucocorticoid therapy
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•
•
•
•
•
•
•
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Following Cushing syndrome cure
Following chronic stress
Postpartum period
Adult post-traumatic stress disorder
Hypothyroidism
Rheumatoid arthritis
Asthma, eczema
Abbreviation: HPA, hypothalamic–pituitary–adrenal.
Stress in Modern Societies
We might wonder why modern societies are plagued by clusters of the so-called multifactorial polygenic disorders:
obesity, the metabolic syndrome and type 2 diabetes mellitus; hypertension; autoimmunity and allergy; anxiety,
insomnia, and depression; and pain and fatigue syndromes. All these disorders are associated with dysfunction of
the stress system ( Table 1 ). Such dysfunction, in fact, has a lot to do with the development of these common and
frequently comorbid pathologies.[68] In its evolutionary path, the human species experienced environmental
stressors, which applied selective pressure upon its genome. Such selection favored ancestors who were efficient at
conserving energy, combating dehydration, fighting injurious agents, anticipating adversaries, minimizing exposure
to danger and preventing tissue strain and damage. In modern societies, lifestyle has changed dramatically from
that of our past. The modern environment and extension of our life expectancy seem to permit the expression of
these affluence-related ills.
Table 1 Adaptive responses to evolutionary stressors and related diseases in modern human
68
societies
Response to survival threat
Combat starvation
Selective advantage
Energy conservation
Contemporary disease
Obesity
Metabolic syndrome
Combat dehydration
Fluid and electrolyte conservation Hypertension
Combat injurious agents
Potent immune reaction
Autoimmunity
Allergy
Anticipate adversaries
Arousal and fear
Anxiety
Insomnia
Minimize exposure to danger
Social withdrawal
Prevent tissue strain and damage Retain tissue integrity
Depression
Pain syndromes
Fatigue syndromes
Stress is ubiquitous and universally pervasive; however, its objective quantification has not been easy. In modern
life, statistics show powerful effects of stress early in life, concurrent chronic stress, and socioeconomic status on
both the morbidity and mortality of chronic disease.[69-74] Similarly, comparisons between non-Hispanic white people
in the US and those in the UK show that the sociopolitical system has a potent effect on the burden of chronic
disease—an influence well above and beyond that predicted by socioeconomic status, which can only be interpreted
as an individual, chronic, stress-driven cacostasis with a deleterious effect on health.[73]
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Finally, analyses of data obtained in the National Health and Nutrition Examination Surveys show that, despite
increasing obesity rates, mortality has been decreasing in the US. This decrease probably reflects public health
improvements and, most likely, chronic use of pharmacological agents, such as ß-blockers, angiotensin-convertingenzyme inhibitors and statins, which interrupt the pathogenic effects of disturbed homeostatic mechanisms.[74]
Conclusions
The stress response, which occurs when homeostasis is threatened or perceived to be threatened, is mediated by
the stress system. Central effectors (including hypothalamic hormones, such as AVP, CRH and proopiomelanocortin-derived peptides and brainstem-derived norepinephrine) and peripheral effectors (including
glucocorticoids, norepinephrine and epinephrine) of this system regulate the brain's cognitive, reward and fear
systems and wake–sleep centers as well as the growth, reproductive and thyroid hormone axes, and influence the
gastrointestinal, cardiorespiratory, metabolic, and immune systems. Malfunction of the stress system might impair
growth, development, behavior and metabolism, which potentially lead to various acute and chronic disorders. Our
lifestyles and environment in modern societies seem to be particularly permissive for such stress-related disorders.
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Key Points
• Stress occurs when homeostasis is threatened or perceived to be so
• The stress response is mediated by the stress system, which is located in both the central nervous system
and peripheral organs
• The main central effectors of the stress system are highly interconnected, and include hypothalamic
corticotropin-releasing hormone and brainstem-derived norepinephrine
• Malfunction of the stress system is associated with behavioral and somatic disorders
• Stress is a major contributor to psychosocial and physical pathological conditions in humans
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Authors and Disclosures
George P. Chrousos, Aghia Sophia Children's Hospital, University of Athens, Athens, Greece.
Competing interests: The author declares no competing interests.
Acknowledgments
This review is partially based on the Geoffrey Harris Memorial Lecture given by the author at the 10th European Congress of
Endocrinology, 3–7 May 2008, Berlin, Germany.
Reprint Address
First Department of Pediatrics, Aghia Sophia Children's Hospital, University of Athens, Thivon and Mikras Asias Streets, Athens 11527,
Greece [email protected]
Nat Rev Endocrinol. 2009;5(7):374-381. © 2009 Nature Publishing Group
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